ATP prevents both hydroperoxide-induced hydrolysis of pyridine nucleotides and release of calcium in rat liver mitochondria

Mitochondrial poly(ADP-ribose) polymerase: The Wizard of Oz at work

Among multiple members of the poly(ADP-ribose) polymerase (PARP) family, PARP1 accounts for the majority of PARP activity in mammalian cells. Although PARP1 is predominantly localized to the nucleus, and its nuclear regulatory roles are most commonly studied and are the best characterized, several lines of data demonstrate that PARP1 is also present in the mitochondria, and suggest that mitochondrial PARP (mtPARP) plays an important role in the regulation of various cellular functions in health and disease. The goal of the current article is to review the experimental evidence for the mitochondrial localization of PARP1 and its intra-mitochondrial functions, with focus on cellular bioenergetics, mitochondrial DNA repair and mitochondrial dysfunction. In addition, we also propose a working model for the interaction of mitochondrial and nuclear PARP during oxidant-induced cell death. MtPARP is similar to the Wizard of Oz in the sense that it is enigmatic, it has been elusive for a long time and it remains difficult to be interrogated. mtPARP - at least in some cell types - works incessantly "behind the curtains" as an orchestrator of many important cellular functions.

Menadione induces a low conductance state of the mitochondrial inner membrane sensitive to bongkrekic acid

When rat liver mitochondria are allowed to cycle Ca(2+) and are incubated in the presence of the pro-oxidant menadione, they undergo swelling, membrane potential (DeltaPsi) collapse, and ion release. These effects, which are inhibited by cyclosporin A (CsA), are fully consistent with the opening of the so-called permeability transition pore. However, when Ca(2+) cycling is abolished by EGTA, the mitochondria remain energized (DeltaPsi collapse and swelling are avoided), but Ca(2+) efflux, promoted by the chelating agent, is stimulated by menadione. This stimulation goes together with the release of Mg(2+), K(+), and adenine nucleotides (AdN) and is inhibited by bongkrekic acid (BKA). The effect of menadione is also characterized by biphasic NAD(P)H oxidation which becomes monophasic in the presence of BKA, CsA, or EGTA and by the oxidation of thiol groups not restrained by the above-mentioned inhibitors. These results suggest that BKA acts indirectly by preserving in the matrix a critical amount of AdN without modifying the monophasic oxidation of pyridine nucleotides by menadione. A critical number of thiol groups also seems to be involved in the phenomenon. Their oxidation most probably causes a conformational change on adenine nucleotide translocase with the opening of the "low-conductance state" of the mitochondrial permeability transition, resulting in ion permeability without DeltaPsi disruption and mitochondrial swelling.

New functions of a long-known molecule. Emerging roles of NAD in cellular signaling

Over the past decades, the pyridine nucleotides have been established as important molecules in signaling pathways, besides their well known function in energy transduction. Similarly to another molecule carrying such dual functions, ATP, NAD(P)+ may serve as substrate for covalent protein modification or as precursor of biologically active compounds. Protein modification is catalyzed by ADP-ribosyl transferases that attach the ADP-ribose moiety of NAD+ to specific amino-acid residues of the acceptor proteins. For a number of ADP ribosylation reactions the specific transferases and their target proteins have been identified. As a result of the modification, the biological activity of the acceptor proteins may be severely changed. The cell nucleus contains enzymes catalyzing the transfer of ADP-ribose polymers (polyADP-ribose) onto the acceptor proteins. The best known enzyme of this type is poly(ADP-ribose) polymerase 1 (PARP1), which has been implicated in the regulation of several important processes including DNA repair, transcription, apoptosis, neoplastic transformation and others. The second group of reactions leads to the synthesis of an unusual cyclic nucleotide, cyclic ADP-ribose (cADPR). Moreover, the enzymes catalyzing this reaction may also replace the nicotinamide of NADP+ by nicotinic acid resulting in the synthesis of nicotinic acid adenine dinucleotide phosphate (NAADP+). Both cADPR and NAADP+ have been reported to be potent intracellular calcium-mobilizing agents. In concert with inositol 1,4,5-trisphosphate, they participate in cytosolic calcium regulation by releasing calcium from intracellular stores.

Oxidant, mitochondria and calcium: an overview

Mitochondria are active in the continuous generation of reactive oxygen species (ROS), (e.g., superoxide), thereby favouring a situation of mitochondrial oxidative stress. Under oxidative stress--for example, ischaemia-reoxygenation injury to cells--mitochondria form superoxide, which in turn is converted to hydrogen peroxide and the potent reactive species, hydroxyl radical. Alternatively, mitochondrial superoxide may react with nitric oxide to form potent oxidant peroxynitrite and as a consequence, mitochondrial function is altered. An increase in the release of calcium from mitochondria by oxidants stimulates calcium-dependent enzymes such as calcium-dependent proteases, nucleases, and phospholipases, which subsequently trigger apoptosis of the cells. In principle, calcium can leave mitochondria by different ways: by non-specific leakage through the inner membrane by "pore formation," by changes in the membrane lipid phase, by reversal of the uniport influx carrier, by the specific calcium/hydrogen (or sodium) antiport system, by channel-mediated release pathways, or by a combination of two or more of these pathways. Additionally, the release of calcium from mitochondria can also occur either by oxidation of internal nicotinamide adenine nucleotides to ADP ribose and nicotinamide or by oxidation of thiols in membrane proteins. Once calcium efflux has been triggered, a series of common pathways of apoptosis are initiated, each of which may be sufficient to destroy the cell. Apoptosis requires the active participation of cellular components, and several genes have been suggested to control apoptosis. The proto-oncogene bcl-2 suppresses apoptosis through mitochondrial effects. Overexpression of bcl-2 in the mitochondrial membrane inhibits calcium efflux, but the underlying mechanisms are not clearly known. Further studies are needed to explore the nature of the apoptosis-inducing pathways, the precise mechanisms of calcium efflux, the molecular partners of bcl-2 oncoproteins at the level of the outer-inner membrane contact sites, the molecular biology of the apoptosis-inducing factor formation and release, and the essential molecular targets of apoptosis-inducing proteases. Clarification of these issues might facilitate the understanding of mitochondrial response on cellular calcium dynamics under oxidant stress.

Control of the pyridine nucleotide-linked Ca2+ release from mitochondria by respiratory substrates

Oxidation of mitochondrial pyridine nucleotides followed by their hydrolysis promotes Ca2+ release from intact liver mitochondria. In most of the previous studies oxidation was achieved with pro-oxidants which were added to mitochondria respiring on succinate in the presence of rotenone, a site I-specific inhibitor of the respiratory chain. Here we investigate pro-oxidant dependent and independent Ca2+ release from mitochondria when respiration is supported either by the NAD(+)-linked substrate beta-hydroxybutyrate, or by succinate. In the presence, as well as in the absence, of the pro-oxidant t-butylhydroperoxide mitochondria retain Ca2+ much better with succinate than with beta-hydroxybutyrate as respiratory substrate. When Ca2+ release is induced by t-butylhydroperoxide succinate-supported Ca2+ retention is impeded by rotenone. Ca2+ release (pro-oxidant dependent or independent) is paralleled by oxidation and hydrolysis of intramitochondrial pyridine nucleotides, and Ca2+ retention is paralleled by reduction of pyridine nucleotides. It is concluded that the pyridine nucleotide-linked Ca2+ release from mitochondria can be controlled by respiratory substrates which regulate the intramitochondrial hydrolysis of oxidized pyridine nucleotides.

Mitochondrial calcium release induced by prooxidants

Hydrogen peroxide, a physiological metabolite, and a variety of other potentially toxic prooxidants, cause oxidation of the pyridine nucleotides NAD(P)H to NAD(P)+ in mitochondria. In Ca(2+)-loaded mitochondria NAD+ thus formed is hydrolyzed to ADP-ribose and nicotinamide. Subsequent to NAD+ hydrolysis, Ca2+ is released from the organelles via a specific pathway which is sensitive to several inhibitors, among them cyclosporine A and some of its derivatives. The release is probably regulated by peptidyl-prolyl cis-trans isomerase. Prolonged stimulation of the release pathway by certain prooxidants followed by re-uptake and release of Ca2+ (Ca2+ 'cycling') leads to collapse of the mitochondrial membrane potential, and is detrimental to the organelles. Excessive Ca2+ 'cycling' is likely to be a basis for the cell toxicity of some prooxidants. On the other hand, the toxicity of inhibitors of the prooxidant-induced Ca2+ release pathway may be due to long-term Ca2+ overloading of mitochondria.

Sensitivity of mitochondrial peptidyl-prolyl cis-trans isomerase, pyridine nucleotide hydrolysis and Ca2+ release to cyclosporine A and related compounds

Prooxidants activate a specific Ca2+ release pathway from mitochondria. Here we investigate the inhibitory potency of cyclosporine A and six related compounds with respect to peptidyl-prolyl cis-trans isomerase (PPIase), pyridine nucleotide hydrolysis and Ca2+ release. Whereas the absolute inhibitory potency of the compounds varies by about three orders of magnitude, a given compound is always most effective on PPIase, followed by pyridine nucleotide hydrolysis, and least effective in Ca2+ release inhibition. The data show that pyridine nucleotide hydrolysis is a prerequisite but not a consequence of Ca2+ release. They also strongly suggest that PPIase participates in the Ca2+ release mechanism from intact mitochondria by regulating the intramitochondrial NAD+ glycohydrolase, and thereby ascribe a physiological function to the protein. Furthermore, a complete lack of correlation between the inhibitory potencies described here and the reported immunosuppressive activities of the drugs is evident.

Prooxidant-induced Ca2+ release from liver mitochondria. Specific versus nonspecific pathways

Ca2+ release from mitochondria can be induced by a variety of chemically different prooxidants. Release induced by these compounds is possibly regulated by protein mono(ADP)ribosylation, and leaves mitochondria initially intact. Excessive "cycling" (continuous release and uptake) of Ca2+ by mitochondria leads to their damage, as shown by a decreased membrane potential, fast Ca2+ release, and impairment of ATP synthesis. When cycling is prevented by Ca2+ chelators or by inhibition of the uptake route with ruthenium red, prooxidants still induce Ca2+ release but mitochondria remain intact. It has recently been suggested that formation of a "pore" in the inner mitochondrial membrane participates in the Ca2+ release mechanism. We find that the prooxidant-induced Ca2+ release is not paralleled by sucrose entry into, or K+ release from, or swelling of mitochondria, provided Ca2+ cycling is prevented. Thus, the prooxidant-induced Ca2+ release does not require formation of a "pore." We conclude that the release occurs via a specific pathway.

Sublethal oxidant stress induces a reversible increase in intracellular calcium dependent on NAD(P)H oxidation in rat alveolar macrophages

A concentration-dependent elevation of intracellular calcium ([Ca2+]i) and oxidation of NAD(P)H occurred in alveolar macrophages during exposure to sublethal tert-butylhydroperoxide concentrations (tBOOH) (< or = 100 microM in 1 ml with 1 x 10(6) cells). Oxidation of NAD(P)H preceded a rise in [Ca2+]i. The elevation of [Ca2+]i was reversible at < 50 microM tBOOH exposure and the return to the steady state [Ca2+]i correlated temporally with repletion of NAD(P)H. At > 50 microM tBOOH, the changes in NAD(P)H and [Ca2+]i were sustained. The relative contributions of NADPH and NADH oxidation were examined by varying the substrates supplying reducing equivalents and by inhibiting glutathione reductase activity. The results suggested that at < 50 microM tBOOH, oxidation of NADPH predominated, while at > 50 microM tBOOH, NADH oxidation predominated. A complex relationship between the relative roles of NADPH and NADH oxidation and the elevation of [Ca2+]i was revealed: (i) reversible oxidation of NADPH is associated with the initial and reversible elevation of [Ca2+]i at < 50 microM tBOOH; (ii) the sustained elevation of [Ca2+]i at > 50 microM tBOOH correlates with the sustained oxidation of NADH; and (iii) the changes in [Ca2+]i did not depend on influx of extracellular Ca2+. We speculate that at low tBOOH, Ca2+ was released from the NADPH/NADP(+)-sensitive mitochondrial Ca2+ pool while higher tBOOH caused additional Ca2+ release from GSH/GSSG-sensitive nonmitochondrial Ca2+ pools with sustained elevation of [Ca2+]i due to decreased mitochondrial Ca2+ reuptake.

Events that precede and that follow S-(1,2-dichlorovinyl)-L-cysteine-induced release of mitochondrial Ca2+ and their association with cytotoxicity to renal cells

Previous studies showed that S-(1,2-dichlorovinyl)-L-cysteine perturbs intracellular Ca2+ homeostasis [Vamvakas et al., Mol Pharmacol 38: 455-461, 1990]. The objective of the present study was to investigate the cellular events that precede and that follow S-(1,2-dichlorovinyl)-L-cysteine-induced mitochondrial Ca2+ release. In incubations with isolated kidney mitochondria, S-(1,2-dichlorovinyl)-L-cysteine-induced Ca2+ efflux is preceded by increased oxidation of mitochondrial pyridine nucleotides and is prevented by ATP, an inhibitor of the hydrolysis of pyridine nucleotides, and by meta-iodobenzylguanidine, an acceptor of ADP-ribose moieties. In LLC-PK1 cells, elevation in the cytosolic Ca2+ concentration is followed by a several-fold increase in DNA double-strand breaks which is attributed to the activation of Ca2+- and Mg(2+)-dependent endonucleases. The formation of DNA double-strand breaks is followed by increased poly(ADP-ribosylation) of nuclear proteins. S-(1,2-Dichlorovinyl)-L-cysteine-induced cytotoxicity in LLC-PK1 cells is blocked by chelation of cytosolic Ca2+ with Quin-2, by inhibition of DNA fragmentation with aurintricarboxylic acid and by inhibition of increased poly(ADP-ribosyl)transferase activity by 3-aminobenzamide. These findings indicate that S-(1,2-dichlorovinyl)-L-cysteine bioactivation in renal cells may initiate the following cascade of events: increased oxidation and hydrolysis of mitochondrial pyridine nucleotides resulting in the modification of mitochondrial membrane proteins by pyridine nucleotide-derived ADP-ribose moieties, followed by Ca2+ release. Elevated Ca2+ concentrations may activate Ca(2+)-dependent endonucleases, which leads to DNA fragmentation followed by increased poly(ADP-ribosylation) of nuclear proteins and, finally, cytotoxicity.

'Pore' formation is not required for the hydroperoxide-induced Ca2+ release from rat liver mitochondria

It has recently been suggested by several investigators that the hydroperoxide- and phosphate-induced Ca2+ release from mitochondria occurs through a non-specific 'pore' formed in the mitochondrial inner membrane. The aim of the present study was to investigate whether 'pore' formation actually is required for Ca2+ release. We find that the t-butyl hydroperoxide (tbh)-induced release is not accompanied by stimulation of sucrose entry into, K+ release from, and swelling of mitochondria provided re-uptake of the released Ca2+ ('Ca2+ cycling') is prevented. We conclude that (i) the tbh-induced Ca2+ release from rat liver mitochondria does not require 'pore' formation in the mitochondrial inner membrane, (ii) this release occurs via a specific pathway from intact mitochondria, and (iii) a non-specific permeability transition ('pore' formation) is likely to be secondary to Ca2+ cycling by mitochondria.

Oxidative stress in mitochondria: its relationship to cellular Ca2+ homeostasis, cell death, proliferation, and differentiation

A variety of chemically different prooxidants causes Ca2+ release from mitochondria. This prooxidant-induced Ca2+ release occurs from intact mitochondria via a route which is physiologically relevant and may be regulated by protein monoADP-ribosylation. When the released Ca2+ is excessively 'cycled' by mitochondria (continuously taken up and released) the inner membrane is damaged. This leads to a decreased ability of mitochondria to retain Ca2+, uncoupling of mitochondria, and an impairment of ATP synthesis, which in turn deprives the cell of the energy necessary for the proper functioning of the Ca2+ ATPases of the endoplasmic (sarcoplasmic) reticulum, the nucleus and the plasma membrane. The ensuing rise of the cytosolic Ca2+ level cannot be counterbalanced by the damaged mitochondria which, under normoxic conditions, act as a safety device against an increase of the cytosolic Ca2+ concentration. The impaired ability of mitochondria to retain Ca2+ may lead to cell death. However, there is also evidence emerging that release of Ca2+ from mitochondria may be physiologically important for cell proliferation and differentiation.

Inhibition of pro-oxidant-induced mitochondrial pyridine nucleotide hydrolysis and calcium release by 4-hydroxynonenal

Intra- and extra-mitochondrial Ca2+ participates in vital cellular processes. This work investigates the influence of 4-hydroxynonenal (HNE) on pro-oxidant-induced Ca2+ release from rat liver mitochondria. Ca2+ movements across the mitochondrial inner membrane, the pyridine nucleotide redox state and pyridine (nicotinamide) nucleotide hydrolysis were analysed. HNE did not influence Ca2+ uptake by mitochondria, but inhibited in a concentration-dependent manner Ca2+ release induced by t-butylhydroperoxide (tbh). Total inhibition was achieved with about 50 microM-HNE. Ca2+ release induced by the pro-oxidant alloxan was also inhibited by HNE. Oxidation of pyridine nucleotides, induced by tbh through the concerted action of glutathione peroxidase, glutathione reductase and the energy-linked transhydrogenase, was not affected by up to 50 microM-HNE. In contrast, HNE inhibited pyridine nucleotide hydrolysis in a concentration-dependent manner. The data suggest that HNE toxicity may be in part attributed to an impaired intramitochondrial Ca2+ homeostasis.

Mechanisms by which mitochondria transport calcium

It has been firmly established that the rapid uptake of Ca2+ by mitochondria from a wide range of sources is mediated by a uniporter which permits transport of the ion down its electrochemical gradient. Several mechanisms of Ca2+ efflux from mitochondria have also been extensively discussed in the literature. Energized mitochondria must expend a significant amount of energy to transport Ca2+ against its electrochemical gradient from the matrix space to the external space. Two separate mechanisms have been found to mediate this outward transport: a Ca2+/nNa+ exchanger and a Na(+)-independent efflux mechanism. These efflux mechanisms are considered from the perspective of available energy. In addition, a reversible Ca2(+)-induced increase in inner membrane permeability can also occur. The induction of this permeability transition is characterized by swelling of the mitochondria, leakiness to small ions such as K+, Mg2+, and Ca2+, and loss of the mitochondrial membrane potential. It has been suggested that the permeability transition and its reversal may also function as a mitochondrial Ca2+ efflux mechanism under some conditions. The characteristics of each of these mechanisms are discussed, as well as their possible physiological functions.

The prooxidant-induced and spontaneous mitochondrial calcium release: inhibition by meta-iodo-benzylguanidine (MIBG), a substrate for mono (ADP-ribosylation)

The norepinephrine analogue meta-iodo-benzylguanidine (MIBG), a substrate for mono(ADP-ribosylation) and inhibitor of eukaryotic ADP-ribosyltransferases, inhibits the prooxidant-induced and spontaneous calcium release from intact rat liver mitochondria without affecting pyridine nucleotide oxidation and hydrolysis. This finding strongly suggests regulation of calcium release by ADP-ribosylation in mitochondria, and may be relevant for the cellular and pharmacological effects of MIBG.

Adenosine formation by isolated rat kidney mitochondria

Isolated rat kidney mitochondria are able to generate extraordinary amounts of adenosine. About one-third of the adenosine formed only results from the degradation of adenine nucleotides. Pyridine nucleotides may contribute to adenosine formation. Nevertheless, there must be an additional, as yet unidentified, acid-insoluble compound in mitochondria which is able to form a significant portion of adenosine.

The mechanism of acute cytotoxicity of triethylphosphine gold(I) complexes. III. Chlorotriethylphosphine gold(I)-induced alterations in isolated rat liver mitochondrial function

Chlorotriethylphosphine gold(I) (TEPAu) is an organo-gold compound that has therapeutic activity in animal models of rheumatoid arthritis. Initial studies have suggested that TEPAu is a potent cytotoxic compound in vitro against a variety of cultured cell types and isolated hepatocytes. Mitochondrial dysfunction induced by this compound has been suggested as a primary biochemical alteration which may result in lethal cell injury in isolated hepatocytes. The purpose of this study was, therefore, to determine the mechanism of TEPAu-induced dysfunction of isolated rat liver mitochondria. TEPAu induced a rapid, concentration-related collapse of the mitochondrial inner membrane potential (EC50 = 24.7 +/- 2.5 microM) which was potentiated in Ca2+ loaded mitochondria (EC50 = 11.3 +/- 3.8 microM). TEPAu-induced collapse of the membrane potential was partially inhibited in the presence of ruthenium red or EGTA. TEPAu caused the rapid release of mitochondrially sequestered Ca2+ which was not inhibited by ruthenium red and, thus, was not via a reversal of the Ca2+ uniporter. TEPAu caused mitochondrial swelling, increased permeability of the inner membrane, and the oxidation/hydrolysis of endogenous mitochondrial pyridine nucleotides. Addition of exogenous ATP slightly reversed the effects of TEPAu on pyridine nucleotides. TEPAu-induced mitochondrial alterations were reversed or inhibited by exposure to the sulfhydryl reducing agent, dithiothreitol. Also, the TEPAu-induced collapse of the mitochondrial membrane potential was partially inhibited by dibucaine, a non-specific inhibitor of phospholipases. These data suggest that TEPAu-induced mitochondrial dysfunction is sulfhydryl dependent. TEPAu-induced mitochondrial dysfunction results in dissipation of the potential difference across the inner mitochondrial membrane which inhibits mitochondrial oxidative phosphorylation. The mechanism by which TEPAu induces the collapse of the membrane potential may be mediated by a sulfhydryl-dependent increase in permeability of the inner membrane to protons.

Kinetic evidence for a heart mitochondrial pore activated by Ca2+, inorganic phosphate and oxidative stress. A potential mechanism for mitochondrial dysfunction during cellular Ca2+ overload

Evidence that the Ca2+-induced permeabilization of mitochondria is attributable to a reversible Ca2+-activated pore [Al Nasser & Crompton (1986) Biochem. J. 239, 19-29] has been further investigated. Permeabilization is induced in a wholly synergistic manner by either Ca2+ plus phosphate or Ca2+ plus tert-butyl hydroperoxide. When permeabilization is complete, extramitochondrial [14C]sucrose equilibrates with the matrix space with a half-time of about 800 ms; [14C]mannitol equilibrates at least threefold faster. Permeabilization is essentially fully reversed on Ca2+ chelation with EGTA, when the half time for [14C]sucrose equilibration is increased 600-1400-fold (to 550-1150 s). A pulsed-flow [14C]solute-entrapment technique has been developed to measure the kinetics of EGTA-induced resealing. The technique incorporates a suitable choice of [14C]solute and an appropriate model for data analysis, and is competent to measure permeation state changes occurring in 100 ms. The data obtained are consistent with exponential resealing of mitochondria in which pores of any single mitochondria close with a high degree of synchrony. The rate of resealing is increased about eight-fold by ADP (half-time approximately 1 s; Km approximately 30 microM). CoA, Mg2+, AMP and also ATP, when account is taken of ADP arising by hydrolysis, are essentially ineffective. It is concluded that heart mitochondria do contain a pore whose permeation state is controlled over an approximate 1000-fold range by Ca2+ and other factors including phosphate, oxidative stress and ADP. The possible involvement of the pore in reoxygenation-induced injury in heart is discussed.

NAD+ depletion and cytotoxicity in isolated hepatocytes

Activation of poly(ADP-ribose)polymerase by DNA damaging agents causes a depletion of intracellular NAD+ and subsequent lowering of ATP pools, which if extensive may lead to cell death. We have studied the cytotoxicity to isolated hepatocytes of dimethyl sulphate, a direct-acting carcinogen and mutagen, hydrogen peroxide, generated by glucose/glucose oxidase, and menadione (2-methyl-1,4-naphthoquinone) in relation to their effects on intracellular NAD+ and ATP levels. Both dimethyl sulphate and glucose/glucose oxidase caused a depletion of NAD+, which was apparently due to an activation of poly(ADP-ribose)polymerase as it was prevented by inhibitors of the polymerase, i.e. 3-aminobenzamide and nicotinamide. This protection of intracellular NAD+ was accompanied by a prevention of the cytotoxicity of both dimethyl sulphate and glucose/glucose oxidase, while it did not alter the decrease in intracellular ATP they induced. This apparent dissociation of effects on ATP from NAD+ does not support the suggestion that activation of poly(ADP-ribose)polymerase leads to a decrease in cellular ATP as a consequence of NAD+ depletion. Menadione also caused a depletion of NAD+ which preceded cytotoxicity, but in contrast to dimethyl sulphate and H2O2 this depletion did not involve poly(ADP-ribose)polymerase as it was not prevented by inhibitors of the enzyme. Our results also indicate that the cytotoxicity of menadione is not mediated by H2O2 alone. Marked depletion of intracellular NAD+ prior to toxicity and a protection against toxicity associated with maintenance of NAD+ suggest a possible role for the maintenance of intracellular NAD+ in cellular integrity.

Control of pyruvate carboxylase activity by the pyridine-nucleotide redox state in mitochondria from rat liver

Pyruvate carboxylation by isolated mitochondria from rat liver is inhibited by t-butylhydroperoxide in a fully reversible manner. The rate of malate formation at 10 mM pyruvate was decreased by some 80% by 30 microM t-butylhydroperoxide. The effective peroxide concentration was dependent on the mitochondrial hydrogen supply, being increased to about 120 microM in the presence of 50 microM palmitoylcarnitine. Regarding the mechanism(s) of the t-butylhydroperoxide action, pyruvate transport and intramitochondrial energy or activator supply are unlikely involved, because the effect also took place with alanine as the substrate and was not accompanied by a change in the intramitochondrial levels of adenine nucleotides and acetyl-CoA respectively. However, t-butylhydroperoxide caused a rapid fall in the 3-hydroxybutyrate/acetoacetate ratio and a marked increase in the oxidized glutathione content. Therefore, experiments were designed to disclose the participation of the respective redox couples in the expression of pyruvate carboxylase activity. From measurements of NADPH, NADH, oxidized and reduced glutathione contents of mitochondria incubated under a variety of conditions, evidence has been obtained indicating that the mitochondrial NADH supply represents an important factor in the regulation of pyruvate carboxylase activity. The results presented seemingly provide a new basis for the understanding of the functional relationship between beta-oxidation and pyruvate carboxylation.

Stimulation of mono (ADP-ribosyl)ation by reduced extracellular calcium levels in human fibroblasts

Lowering extracellular calcium in cultures of human diploid fibroblast-like cells caused a rapid depletion of NAD pools. This loss of NAD was reversed by restoring extracellular Ca2+ and was inhibited by 3-aminobenzamide, an inhibitor of ADP-ribosyl transfer reactions. The concentrations of 3-aminobenzamide needed to inhibit the loss of NAD were consistent with those required to inhibit cellular mono(ADP-ribosyl) rather than poly(ADP-ribosyl) reactions. Calcium depletion did not inhibit the biosynthesis of NAD. These results suggest that mono(ADP-ribosyl)ation is involved in the regulation of cellular Ca2+ levels.

Ca2+ release from mitochondria induced by prooxidants

A variety of chemically different prooxidants causes Ca2+ release from mitochondria. The prooxidant-induced Ca2+ release occurs from intact mitochondria via a route which is physiologically relevant and may be regulated by protein ADP-ribosylation. When the released Ca2+ is excessively cycled by mitochondria they are damaged. This leads to uncoupling, a decreased ATP supply, and a decreased ability of mitochondria to retain Ca2+. Excessive Ca2+ cycling by mitochondria will deprive cells of ATP. As a result, Ca2+ ATPases of the endoplasmic (sarcoplasmic) reticulum and the plasma membrane are stopped. The rising cytosolic Ca2+ level cannot be counterbalanced due to damage of mitochondria which, under normoxic conditions, act as safety device against increased cytosolic Ca2+. It is proposed that prooxidants are toxic because they impair the ability of mitochondria to retain Ca2+.

Menadione (2-methyl-1,4-naphthoquinone)-induced Ca2+ release from rat-liver mitochondria is caused by NAD(P)H oxidation

Incubation of rat-liver mitochondria with menadione in the presence of succinate and rotenone resulted in rapid glutathione and NAD(P)H oxidation followed by Ca2+ release and mitochondrial swelling. Ca2+ release, NAD(P)H oxidation and mitochondrial swelling, were also observed in mitochondria from selenium-deficient rats. Glutathione was only slowly oxidized, suggesting that glutathione oxidation, and subsequent NAD(P)H oxidation via the glutathione peroxidase-glutathione reductase system were not required for Ca2+ release by menadione. Isocitrate prevented and reversed Ca2+ release dose-dependently but dicoumarol had no effect indicating that NADH-ubiquinone oxidoreductase and not DT-diaphorase was responsible for NAD(P)H oxidation. Superoxide anion radical was formed by cyanide-resistant respiration, suggesting that menadione undergoes a one-electron reduction to an autoxidizable semiquinone radical by NADH-ubiquinone oxidoreductase. The inability of menadione to oxidize glutathione in selenium-deficient mitochondria indicates that the metabolism of the superoxide dismutation product, H2O2, by glutathione peroxidase was probably responsible for the glutathione oxidation in selenium-replete mitochondria.

Ca2+ transport in isolated mouse liver mitochondria; role of reductive carboxylation and citrate?

The uptake of Ca2+ in isolated mouse liver mitochondria respiring on succinate in the presence of rotenone and added Pi, was inhibited by dibucaine, fluorocitrate, p-hydroxymercuribenzoate (PMB), malonate, palmitoyl-CoA, succinyl-CoA and trifluoroperazine. The release of accumulated Ca2+ was stimulated by arsenite, malonate, PMB, palmitoyl-CoA and succinyl-CoA, whereas the release was inhibited by dibucaine, fluorocitrate, trifluoroperazine, and by oligomycin, especially in the presence of ADP. The pyridine nucleotides were oxidized in mitochondria incubated with PMB. The observations suggest a possible contributory role of reductive carboxylation for the uptake of Ca2+, and a possible role of citrate for the retention of Ca2+ in isolated mouse liver mitochondria.

t-Butylhydroperoxide-induced Ca2+ efflux from liver mitochondria in the presence of physiological concentrations of Mg2+ and ATP

Isolated rat liver mitochondria, energized either by succinate oxidation or by ATP hydrolysis, present a transient increase in the rate of Ca2+ efflux concomitant to NAD(P)H oxidation by hydroperoxides when suspended in a medium containing 3 mM ATP, 4 mM Mg2+ and acetate as permeant anion. This is paralleled by an increase in the steady-state concentration of extramitochondrial Ca2+, a small decrease in delta psi and an increase in the rate of respiration and mitochondrial swelling. With the exception of mitochondrial swelling all other events were found to be reversible. If Ca2+ cycling was prevented by ruthenium red, the changes in delta psi, the rate of respiration and the extent of mitochondrial swelling were significantly diminished. In addition, there was no significant decrease in the content of mitochondrial pyridine nucleotides. Mitochondrial coupling was preserved after a cycle of Ca2+ release and re-uptake under these experimental conditions. It is concluded that hydroperoxide-induced Ca2+ efflux from intact mitochondria is related to the redox state of pyridine nucleotides.

Formation of activated oxygen in the hypoxic rat liver

The biliary GSSG efflux rate of normoxic perfused rat liver was 1.5 +/- 0.2 nmol/min/g liver wet weight. The GSSG efflux rate as indicator for the flux through the glutathione peroxidase reaction and, therefore, for an oxidative loading increased with the extent of hypoxia. 2.6 +/- 0.5 nmol/min/g were released from the severely hypoxic liver. The hydroxyl radical scavenger formate as well as the xanthine oxidase inhibitor allopurinol reduced the efflux rate of GSSG. GSH was released from the perfused liver at a rate of 15.5 nmol/min/g which was nearly unchanged in severe hypoxia. The high rate of glucose liberation from the hypoxic liver declined to almost that of the normoxic organ in the presence of formate. There is an 'oxidative stress' during hypoxic liver perfusion which probably originates from increased generation of activated oxygen species in the degradation of purine nucleotides.

Quantitative and mechanistic aspects of the hydroperoxide-induced release of Ca2+ from rat liver mitochondria

We have previously demonstrated in rat liver mitochondria a hydroperoxide-induced hydrolysis of pyridine nucleotides and release of Ca2+ [Lötscher, H. R., Winterhalter, K. H., Carafoli, E. & Richter, C. (1979) Proc. Natl Acad. Sci. USA 76, 4340-4344, and Lötscher, H. R., Winterhalter, K. H., Carafoli, E. & Richter, C. (1980) J. Biol. Chem. 255, 9325-9330]. Here we investigate pyridine nucleotide hydrolysis and Ca2+ release under conditions of minimized Ca2+ cycling and with smaller Ca2+ loads. The extent of pyridine nucleotide hydrolysis, measured by pyridine-nucleotide-derived nicotinamide release from intact mitochondria, and the Ca2+ release rate show a very similar sigmoidal dependence on the mitochondrial Ca2+ load. The hydrolysis of oxidized pyridine nucleotides is limited under non-cycling conditions. Whereas pyridine nucleotide hydrolysis as measured by nicotinamide release is extensive, net loss of mitochondrial pyridine nucleotides is observed only at relatively high Ca2+ loads. Our results indicate the ability of mitochondria to resynthesize pyridine nucleotides after hydrolysis. Neither a decrease of reduced, nor an increase of oxidized, mitochondrial glutathione favour Ca2+ release. From these and previous findings it is concluded that the hydroperoxide-induced Ca2+ release is triggered by a factor which is distal to the oxidation of mitochondrial pyridine nucleotides. Ca2+ release is stimulated when the movement of protons across the inner mitochondrial membrane is facilitated, giving evidence for the operation of the hydroperoxide-induced release pathway as a Ca2+/H+ antiport.

The role of hydroperoxides as calcium release agents in rat brain mitochondria

Hydroperoxides have previously been shown to induce Ca2+ release from intact rat liver mitochondria via a specific release pathway. Here it is reported that, in rat brain mitochondria, a hydroperoxide-induced Ca2+ release is also operative but is of minor importance. Hydroperoxide stimulates Ca2+ release in the presence of ruthenium red about twofold at a Ca2+ load of 40 nmol/mg mitochondrial protein. After addition of hydroperoxide, Ca2+ release from brain mitochondria can still be evoked by Na+. In the presence of succinate and rotenone, hydroperoxide induces only a very limited oxidation of pyridine nucleotides, most probably due to the low level of glutathione peroxidase (EC 1.11.1.9) and glutathione reductase (EC 1.6.4.2) found in brain mitochondria. Similar to liver mitochondria, a NADase (EC 3.2.2.5) activity is found in brain mitochondria. Its localization and sensitivity toward ADP and ATP, however, is different from that of the liver mitochondrial enzyme.

Nonenzymic ADP-ribosylation of specific mitochondrial polypeptides

The apparent NAD:protein ADP-ribosyl transferase activity of mitochondria and submitochondrial particles from beef heart and rat liver is simulated by a reaction sequence that consists of an enzymic hydrolysis of NAD to ADP-ribose (ADP-Rib) by NAD glycohydrolase(s) and a nonenzymic ADP-ribosylation of acceptor proteins by the free ADP-Rib formed. The nonenzymic ADP-ribosylation of mitochondrial proteins showed two pH optima and exhibited the same remarkable selectivity as the reaction with NAD. The predominant acceptor in beef heart mitochondria was a 30-kDa protein, whereas in mitochondrial extracts of rat liver a 50-55 kDa polypeptide served as an acceptor. No authentic ADP-Rib transferase activity could be detected even when free ADP-Rib was trapped by NH2OH. Once formed, the mitochondrial ADP-Rib conjugates were resistant to hydroxylamine. NH2OH-resistant mono(ADP-Rib)-protein conjugates as found in most cells may also be products of nonenzymic ADP-ribosylation. In mouse tissues, their amounts relate to protein and NAD contents, and they increase specifically and reversibly in the hypothyroid status. Furthermore, intact rat liver mitochondria contain a mono(ADP-Rib)-polypeptide (50-55 kDa) that appeared to be identical with the polypeptide reacting with ADP-Rib in vitro.

Pyridine-nucleotide oxidation, Ca2+ cycling and membrane damage during tert-butyl hydroperoxide metabolism by rat-liver mitochondria

As tert-butyl hydroperoxide is metabolized by the glutatione peroxidase--glutathione reductase enzyme system present in liver mitochondria, rapid and extensive oxidation of NADH and slow NADPH oxidation are observed. This NAD(P)H oxidation can be prevented, or reversed, more effectively by 2-hydroxybutyrate than by isocitrate, indicating an important role of mitochondrial NAD(P)+ transhydrogenase activity in maintaining a high NADPH/NADP+ ratio for glutathione reductase. In Ca2+-loaded mitochondria tert-butyl hydroperoxide-induced NAD(P)H oxidation is followed by Ca2+ release from the mitochondria. If either 2-hydroxybutyrate or isocitrate is present, no Ca2+ release can be induced by the hydroperoxide. Following Ca2+ efflux the NAD(P)H oxidation process becomes irreversible and membrane damage occurs. These late effects do not take place if ruthenium red is added to prevent re-uptake of released Ca2+ by the mitochondria. Thus, we conclude that the metabolism of tert-butyl hydroperoxide leads to a release of mitochondrial Ca2+ via oxidation of pyridine nucleotides, and that subsequent membrane damage is not directly associated with this Ca2+ efflux but results from continued cycling of released Ca2+.

Increase in cytosolic Ca2+ concentration during t-butyl hydroperoxide metabolism by isolated hepatocytes involves NADPH oxidation and mobilization of intracellular Ca2+ stores

Activation of phosphorylase a in hepatocytes incubated with t-butyl hydroperoxide indicates that hydroperoxide metabolism is associated with an increase in cytosolic free Ca2+ concentration which appears to be mediated by NADPH oxidation and to involve mobilization of intracellular Ca2+ stores.

Possible participation of membrane thiol groups on the mechanism of NAD(P)+-stimulated Ca2+ efflux from mitochondria

NAD(P)+-stimulated Ca2+ efflux from mitochondria is inhibited by bongkrekate and slightly stimulated by carboxyatractylate. Addition of oxaloacetate, an NAD(P) oxidant, or diamide, a thiol oxidant, to de-energized mitochondria incubated in Ca2+ -free medium induced a small decrease in turbidity of the mitochondrial suspension compatible with small structural changes of mitochondria. Similar to NADP+-stimulated Ca2+ efflux these changes were also inhibited by bongkrekate and slightly stimulated by carboxyatractylate. The similarity between the effects of oxaloacetate and diamide, on both Ca2+ efflux and mitochondrial structure, indicates the existence of a common denominator, possibly the oxidation of specific thiol groups, regarding the mechanism by which these agents stimulate Ca2+ efflux from mitochondria.

Inhibition of oxidative phosphorylation by a Ca2+-induced diminution of the adenine nucleotide translocator

The mechanism through which internal Ca2+ inhibits oxidative phosphorylation of rat heart mitochondria has been explored. In parallel to a Ca2+-induced diminution of the activity of the adenine nucleotide translocator, an efflux of internal adenine nucleotides is observed. The efflux of adenine nucleotides depends on the amount of Ca2+ accumulated by the mitochondria and on the time that Ca2+ remains in the mitochondria; this efflux is atractyloside insensitive. These results suggest that internal Ca2+, by inducing a lowering of the internal concentration of adenine nucleotides, diminishes the rate of exchange of adenine nucleotides via the translocase, and in consequence of oxidative phosphorylation. Under conditions in which the Ca2+-induced release of adenine nucleotides takes place, no gross changes of the permeability properties of the membrane are observed. As revealed by studies with arsenate, respiratory activity and the function of the ATPase in the direction of ATP synthesis are not affected by internal Ca2+.